Method and device for brewing coffee and espresso drinks

ABSTRACT

Method for brewing fresher coffee comprises introducing hot liquid to roasted coffee grounds in a container to form a dispersion and a layer of floated grounds, tilting container to generate a liquid head on a first surface of a filter to drive the dispersion through the filter to its second surface as coffee and breaking the layer of floated grounds by swirling or shaking the container. The method further comprises regenerating the filter by moving the container in such a way to cause the liquid to wash the grounds on the filter back into the container and adding ice into the dispersion to quench the extraction, thereby preventing over-extraction of coffee grounds and improving coffee taste. The method may further comprise providing an extraction chamber to enclose the roasted coffee grounds and an exchange chamber and causing the liquid in the exchange chamber to interchange with the dispersion in the extraction chamber through the filtration openings to raise the concentration of flavor components in the exchange chamber, thereby producing in the exchange chamber a reservoir of fresh coffee substantially free of coffee grounds ready for drinking or dispensing.

FIELD OF THE INVENTION

[0001] This is a continuation in part application of the application Ser. No. 09/944,998 filed Sep. 1, 2001 and International application number PCT/US02/36899 filed Nov. 16, 2002.

BACKGROUND OF THE INVENTION

[0002] Beverages such as coffee and espresso drinks are commonly brewed by causing hot water to pass through the coffee grounds above a disposable or permanent filter either under gravity in case of manual or automatic drip coffee maker or under pressure in case of espresso machines.

[0003] Such devices, although popular, have numerous drawbacks such as inconsistent brew quality and lack of the original aroma in the roasted beans. The quality of coffee and espresso brewed varies significantly when coffee grounds of different sizes are used. When grounds is too coarse, the resulting brew is watery; when too fine, the brewing becomes very slow or even stops. The coffee or espresso brewed lacks the aroma or alluring smell of the ground coffee, even when it is made expensive commercial machines in premium coffee shops.

[0004] Other drawbacks include bulky size, complicated brewing process, high manufacturing cost, and time-consuming cleaning. Such devices normally take a space over four times larger than the volume of beverage they are designed to brew, which becomes an issue as the countertop or desktop becomes increasingly crowded. The brewing process, especially for espresso machines, involves many steps such as adding grounds to filter, mounting filter, filling water reservoir, heating and pumping water, placing cup or carafe under the basket, is too complex for some people. The manufacturing cost, especially for espresso machines, is very high since numerous components such as heater and pump, reservoir, a brew head, brew basket, basket holder, carafe, housing are required. Finally, such devices require a user to clean many parts such as filter basket, holders, carafe, brew head and cups, which, although not difficult, is a major nuance for many people.

[0005] The inventor in U.S. Pat. No. 5,638,740 provided a coffee and espresso device for making better tasting coffee and espresso by transforming the brewed beverage from coffee filter into a high-speed jet. The jet is arranged to inject into the coffee or espresso maintained in a containing means to generate a layer of visually crema in the cup. One issue with this improved device is that it still requires the delivery of liquid through the ground coffee, which increases the complexity, cost and size of the device.

SUMMARY OF THE INVENTION

[0006] The invention provides an innovatively simple device and method for brewing better and fresher beverages in a container from a supply of flavor-containing materials. The method comprises a step of introducing hot liquid to a supply of flavor-containing materials comprising roasted coffee grounds in a container, which container is sufficiently large to allow the formation of a dispersion containing the liquid and flavor-containing materials and the formation of a layer of floated roasted coffee grounds on top of the dispersion, a step of tilting the container to generate a liquid head to act on a first surface of a porous filter to drive the dispersion through the filtration openings to a second surface of the porous filter as a coffee beverage, and a step of breaking the layer of floated roasted coffee grounds by a step of swirling or shaking the container to prevent the clogging of the porous filter by the layer of floated flavor-containing materials and increase the beverage flow during said step of tilting.

[0007] The method may further comprise a step of regenerating the porous filter by moving the container in such a way to cause the liquid therein to wash the roasted coffee grounds accumulated on the first surface of the porous filter off into the container and a step of resting the container in a still position for a period of time after the step of breaking to further increase of the filtration flow through the filtration openings. The method further comprises providing a flow facilitator having a plurality of selective openings adapted to be sufficiently small to restrict the flavor-containing materials from passing through during the steps of breaking and tilting and adapted to be or become sufficiently permeable to air to allow air to enter the container during the step of tilting. The method may further comprise a step of adding an amount of ice into the container to quench or stop the extraction of the roasted coffee grounds, thereby preventing over-extraction of the roasted coffee grounds by hot liquid and improving the taste of the resulting coffee beverage.

[0008] The step of introducing liquid may comprises a step of introducing liquid into an extraction chamber containing the supply of flavor-containing materials and into an exchange chamber. The method further comprises a step of causing the liquid in the exchange chamber to interchange with the liquid extraction in the extraction chamber through the filtration openings of the porous filter to cause the concentration of the flavor components in the liquid in the exchange chamber to increase by swirling, shaking, vibrating or repetitively tilting back and forth the container, thereby producing in the exchange chamber a reservoir of coffee beverage substantially free of coffee grounds and ready for drinking or dispensing.

[0009] It is an object of the present invention to provide a device and method for making better tasting beverage from flavor-containing materials with a visually appealing top crema layer.

[0010] It is a further object of the present invention to provide a device and method for grounding, extracting and filtering the flavor-containing materials in the same container to capture all the aroma in the resulting beverage.

[0011] It is a further object of the present invention to provide a device and method that are simple, intuitive and has little or even no need to clean after usage.

[0012] It is a further object of the present invention to provide the most compact beverage device that is nearly as small as the volume of the beverage it brews at a time.

[0013] It is a further object of the present invention to provide a low cost beverage brewing device and a brewing device that can be affordable to be disposed after one use.

[0014] These and other objectives and advantages of the present invention will become apparent from the following description of the preferred embodiments, taken together with the accompanying drawings.

DESCRIPTION OF THE DRAWINGS

[0015] The accompanying drawing illustrates diagrammatically non-limitative embodiment of the invention, as follows:

[0016]FIG. 1 is a sectional view of a first embodiment of a beverage-making device;

[0017]FIG. 1a is a sectional view for the flow facilitator along line a-a shown in FIG. 1;

[0018]FIG. 1b is a sectional view for the beverage-making device shown in FIG. 1 in a tilted position for discharging the beverage therein;

[0019]FIG. 2 is a sectional view of a second embodiment of the beverage-making device;

[0020]FIG. 2a is a sectional view along line a-a shown in FIG. 2;

[0021]FIG. 3 is a sectional view of a third embodiment of the beverage-making device;

[0022]FIG. 3a is a sectional view along line a-a shown in FIG. 3;

[0023]FIG. 3b is a sectional view for the beverage-making device shown in FIG. 3 in a tilted position for discharging the beverage therein;

[0024]FIG. 4 is a sectional view of a forth embodiment of the beverage-making device;

[0025]FIG. 4a is a top view of the beverage-making device of FIG. 4.

[0026]FIG. 5 is a sectional view of a fifth embodiment of the beverage-making device;

[0027]FIG. 5a is a sectional view of an alternative brew head assembly for the beverage device of FIG. 5;

[0028]FIGS. 6a-b are partially sectional, partially schematic views of two alternative brew head assembly for the beverage-making device of FIG. 1;

[0029]FIG. 7 is a partially sectional, partially schematic view of a sixth embodiment of the beverage device;

[0030]FIG. 8 is a sectional view of a seventh embodiment of the brewing device;

[0031]FIG. 8a is a sectional view for the device of FIG. 7 showing the coffee having a natural crema layer made by the device.

[0032]FIG. 9 is a sectional view of an eighth embodiment of the brewing device showing an iced latte made by the device;

[0033]FIG. 10 is a sectional view of a ninth embodiment of the brewing device showing an iced coffee made by the device.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0034]FIGS. 1, 1a and 1 b shows certain parts of a device 10 for making beverages. Only those parts of the device are shown which are necessary for full understanding of the invention. Beverage device 10 comprises a container for receiving a supply of flavor-containing materials 37 and liquid and allowing the liquid to extract the flavor-containing materials therein, a heater assembly 39 supported by housing 38 and controlled by a thermal control means such as a thermostat 40 for heating the container and the content therein, and a brew head assembly 21 for facilitating the extraction of the flavor-containing materials and filtering the flavor-containing materials. The container 12 includes a top opening 17 for receiving the brew head assembly, a neck 16, a bottom 14, a bottom chamber 36 for the flavor-containing materials, a upper chamber 35 for the liquid and the resulting flavor-containing materials/liquid dispersion 11 and a top crema layer 15, and handle 33 for a user to hold and tilt the container to pour or drink the filtered beverage 44.

[0035] The assembly 21 comprises a body 18 for connecting to the top opening 17 of the container, a porous filter 20 attached to the lower end of the body having numerous filtration openings dimensioned to allow the beverage 44 to pass through but block the flavor-containing materials in the dispersion 11, a transient beverage chamber 23 for collecting the beverage from the porous filter, a blending/mixing mechanism 78 connected to the body 18 for producing the visually appealing top crema layer 15 on the dispersion 11, and a flow facilitator 27 located on the porous filter for increasing the flow of the liquid extraction or beverage 44 through said filtration openings and preventing the flavor-containing materials from getting out of the container in the event that the dispersion covers or reaches the selective opening under a liquid head or force. The body 18 has handle 24 for facilitating the handling of the brew head assembly, an o-ring 19 for forming a seal with the neck 18 of the container, a beverage outlet 22 from which the filtered beverage 44 is poured or drunk, a top cover 25 for the transient beverage chamber, and an vent 28 for venting the transient beverage chamber 23.

[0036] The blending/mixing mechanism 78 may perform one or several functions, including generating the crema or foam layer 15, mixing the flavor-containing materials and liquid, trapping the grounds in the bottom chamber 36 of the container, grinding the flavor-containing materials, and blending different ingredients for a beverage, as shown in this and later exemplar embodiments. The blending/mixing mechanism 78 in FIG. 1 comprises a plate member 14 and a rod 32 for connecting the plate member to the body 18. The plate member has a plurality of holes 34 for allowing the flavor-containing materials and fine air bubbles to pass through and minimizing the amount of flavor-containing materials that may be retained above the plate member. The holes 34 are taped with the top opening larger than the bottom opening to facilitate the flavor-containing materials to pass through downwards when the plate member 14 is moved upward. The plate member 14 and rod 78 are dimensioned to allow the plate member to cover or partially cover the bottom chamber 36 to prevent or restrict the flavor-containing materials that precipitates from the dispersion 11 to the bottom chamber from being re-dispersed after the body 18 is connected to the container as shown in FIG. 1b. The extracted or partially extracted flavor-containing materials below the plate member 14 is heated or even “re-roasted” by the heater 39, causing additional flavor or/and aroma out of the flavor-containing materials.

[0037] It is found that by moving the plate member 14 up and down within the dispersion 11 in the container, a visually appealing crema layer 15 is generated on top of the dispersion. To display the crema layer 15 on top of the dispersion 11 produced by the blending/mixing mechanism, the porous filter 20, container 12 and/or the cover 25 may be transparent or translucent. It is also found that some porous filters, such as those filters made from polymeric materials that have similar refractive index as the liquid, become transparent or more transparent after being wetted by the liquid or the dispersion 11. It is also found, with much surprise, and will be described in details in FIGS. 2-3 that the plate member 14 may be replaced by a small ball 42 or even be removed to allow the rod 32 itself to function as the blending/mixing mechanism.

[0038] It is appreciated that the rod 32 can be slidingly mounted in an opening on the cover 25 to allow a user to move the rod 32 and the plate member 14 up and down within the container while the body I 8 is mounted to the container (not shown). It is also appreciated that the plate member 14 may adopt other shapes such as an arc shape or a blade shape, which will be discussed in more detail in FIGS. 6a and 7.

[0039] The flow facilitator 27 functions not only to increase the beverage flow rate through the filtration openings of the porous filter 20 by allowing air to enter the container 12 to prevent the formation of vacuum therein, but also to prevent or restrict the flavor-containing materials in the dispersion 11 from getting out in the event that the flow facilitator is covered by the dispersion 11 under pressure or a liquid head. Therefore, the users or consumers are always ensured that that no flavor-containing materials, which can be unpleasant when present in the beverage to be drunk, will get out of the container 11 when the body 18 is mounted to the container. The flow facilitator can be a check valve as exemplified in FIGS. I and Sa and be a plurality of quasi-filtration openings as exemplified in FIGS. 2-7. In all examples, the flow facilitator has a selective opening 29 adapted to allow air to enter container 11, but to prevent or restrict the flavor-containing materials in the dispersion 11 from getting out of the container.

[0040] The facilitator 27 of FIG. 1 is a check valve comprises a base 30 for attaching the check valve to the porous filter 20 and the selective opening 29 inserted into a sufficiently large opening formed on the porous filter at a location farthest from beverage outlet 22. It is, however, appreciated that facilitator 27 can be located at other locations on porous filter 20 or on the body 18 or container 12. The selective opening 29 comprises two resilient elongated walls 31 and two resilient connection walls 42 for connecting the two elongated resilient walls 31. The connection walls are wider near the base 30 and become narrower when approaching the lower end of the valve. This design makes selective opening 29 decrease in size from the base to its lower end and become small enough or even closed at the lower end to prevent the flavor-containing materials in the dispersion 11 from passing through. The lower end of the selective opening becomes larger when the container 12 is tilted to generate a liquid head between the upper level of the dispersion 11 inside the container and the level of the beverage 44 at the beverage outlet 22, therefore allowing air to enter the container to take the space vacated by the beverage leaving the container through the porous filter 20. It was found that the lower end of the selective opening 29 stays small or closed when the dispersion 11 reaches over or covers the elongated walls 31 and when the container is tilted in the non-intended directions.

[0041] It is appreciated that a vent comprising a large opening that can allow air, the dispersion and the flavor- containing materials to pass through may be used to replace the flow facilitator 27 for increasing the filtration flow if it is acceptable to have some flavor-containing materials in the beverage or the vent can be so located that the dispersion 11 can not reach it during normal use. Such a vent can be located on a particular area of the container 11 or body 18. It is also appreciated that such a vent can be attached to the porous filter 20 or formed directly on the porous filter to reduce the complexity and cost of the beverage device.

[0042] The heater 39 may be permanently attached or removably engaged to the container 12 to conduct heat to the liquid and flavor-containing materials. The thermal control means may be selected to turn off the heater when or before the liquid reaches its boiling temperature to prevent overflow of the dispersion 11 in the container and reduce the deterioration of the flavor or aroma in the beverage prepared by the device. The flavor-containing materials may be extracted by directly adding hot liquid into the container.

[0043] In this and other exemplar embodiments, the container 12 can be made from metal such as stainless steel or aluminum, ceramic or porcelain, glass, paper, plastic foam or plastic materials or any combination of such materials. If the container is intended to contact or in heat-conducting relation with a gas or electric heater for heating the liquid and flavor-containing materials therein, it is preferred to use more heat conductive materials (metal, etc.) as at least the bottom of the container to increase the nucleation centers for steam bubbles thereon, thus reducing or preventing potential overflow of the dispersion 11 when heated. The container can be a carafe, pot, jar, can, bottle, pitcher, thermos, cup or any other vessel that can contain liquid. The porous filter 20 can be a cloth, screen, wire-mesh, woven, non-woven, expanded plastic, etched, punctured or injection molded filter and be made from plastic, metal, glass or elastomer. The liquid can be hot or cold water, milk, alcoholic drinks, soft drinks, fruit juices or any other liquid that can extract flavor or aroma from the flavor-containing materials 3 7. The flavor-containing materials can be coffee grounds, tea, coca, chocolate powder, milk powder, herb, fruit, meat, vegetables, grains, any combination, or any other materials which contains flavor or aroma. The beverage made by the device can be coffee, espresso, latte, mocha, tea, iced drinks, hot chocolate, blended drinks, fruit juices or any other edible fluids.

[0044] To use the beverage device 10 of FIG. 1 to make coffee or espresso, a desired amount of liquid is added into the container 12 and heated by the heater 39 to a predetermined temperature. A desired amount of ground coffee is then added to the hot liquid. Normally, at least some of the ground coffee, although soaked in the liquid, remains on the surface of the liquid. To generate a visually appealing layer of crema, the user simply repetitively moves the plate member 14 up and down in the container by holding the handle 24 or the body 18. Also as a result of such movement, the ground coffee become better dispersed in the container and the coarser ground coffee becomes precipitated to the bottom 41 of the container. The user then inserts the body 18 of the brew head assembly 21 into the opening 17, which result in a water-tight seal between the neck 16 of the container and the o-ring 19 on the body and the trapping of the coffee grounds in the bottom chamber 36 by the plate member 14. To pour coffee or to drink the coffee directly from the beverage outlet 22, the user simply tilts the container when holding the handler 33. The tilting causes a liquid head between the top level of the dispersion 11 and the beverage level at the beverage outlet 22 or the transient beverage chamber 23. The liquid head drives the beverage part of the dispersion 11 out of the container through the filtration openings of the porous filter 20. The selective opening 29 of the flow facilitator 27 opens up to allow air to enter the container 12 to prevent vacuum formation therein as the beverage exits the container, therefore facilitating the filtration flow through the porous filter.

[0045] If the crema layer 15 is not desired, the user may omit the step of moving the plate member 14 up and down in the container, thus simplifying the brewing process. It is appreciated that the ground coffee can be added into the container 12 any time, either before or after the water is added or heated. It is also appreciated hot or boiling water can be poured into the container and the ground coffee therein to avoid the need to heat the container, which makes it possible to use less heat resistant materials such as paper, foamed plastics or plastics for the container to lower the container cost. To make milk-containing coffee beverages such as latte and cappuccino, water/milk or milk alone is added to the container instead of water. Powdered milk, cocoa and/or chocolate can be added to the container to make milk and chocolate-containing coffee or espresso drinks. To make iced beverages, ice can be added, and may be broken by the blending/mixing mechanism 78, after the extraction has been completed. Other flavoring liquid or solid such as wine, syrups, cinema oil, fruits or fruit juices may also be added.

[0046] In the exemplar embodiment described in FIGS. 2 and 2a, an alternative blending/mixing mechanism 78 and an alternative flow facilitator 27 are provided for the brew head assembly 21. In the alternative blending/mixing mechanism 78, a small ball 42 is located at the end of the rod 32 to replace the plate member 14 of FIG. 1. To use the alternative blending/mixing mechanism, the user holds the handle 24 to insert the ball 42 and part of the rod 32 into the liquid and move the rod and ball in a substantially circular motion, which causes a layer of crema 15 to be formed on top of the dispersion 11 and some coarser ground coffee to precipitate to the bottom of the container 12. The user then mounts the assembly to the opening 17 of the container by inserting the body 18 into the container and forming a friction fit between the body 18 and the interior surface of the container to prevent the brew head assembly from being pushed out by the dispersion when the container is tilted. The lip 76 of the opening 17 of the container may protrude a little inwardly to prevent the body 18 from being pushed out by the dispersion 11 when the container 12 is tilted to generate a liquid head to drive the beverage out of the container through the porous filter 20. Here, the opening 17 of the container functions as the beverage outlet from which the beverage is poured or drunk.

[0047] In this alternative flow facilitator 27, the selective openings 29 comprise quasi filtration openings which are substantially cylindrical in shape and have larger size than the filtration openings of the porous filter 20. It is, however, appreciated that the quasi filtration openings can adopt square, rectangle, oval or other suitable shape. The cylindrical quasi filtration openings have significantly longer flow path, thus significantly higher flow resistance, for the beverage than the filtration openings of the porous filter, which, in combination with the few number of quasi filtration openings, makes the amount of beverage through the quasi filtration openings negligible compared to the amount of beverage through the filtration openings of the porous filter despite the larger size of the quasi filtration openings. As a result, even if the quasi filtration openings allow some fine particles or flavor-containing materials to pass through, the amount is sufficiently small that the quality of the resulting beverage will not be measurably deteriorated.

[0048] To prevent the quasi filtration openings from being blocked by the liquid or beverage that may stay in the quasi filtration openings due to capillary force, the quasi filtration openings are so dimensioned that a very small vacuum in the container is sufficient to pull the liquid in the openings back into container to clear up the quasi filtration openings for air to pass through. The vacuum or pressure at which the liquid in the quasi filtration openings is pulled or pushed back into the container is referred as the liquid breakthrough pressure in this application. It was found that the liquid breakthrough pressure depends on the size and shape of the quasi filtration openings, the material used to construct the quasi filtration openings and the surface tension of the liquid and the dispersion 11. Sufficiently low liquid breakthrough pressure for the quasi filtration openings is critical for achieving sufficiently high beverage flow rate through the filtration openings of the porous filter when the container is tilted to generate the liquid head. The liquid breakthrough pressure for the quasi filtration openings is preferred to be less than about two inches of liquid head, and is more preferred to be less than one inch of liquid head. It is appreciated that too low a liquid breakthrough pressure normally requires the quasi filtration opening to have relatively large size, which may allow unacceptably large flavor-containing materials to pass through, while too high a liquid breakthrough pressure may cause too much beverage left in the container at the end of the brewing or require the liquid head generated by the tilting of the container 12 to be sufficiently high to clear up the quasi filtration openings for air flow.

[0049] To facilitate the flavor-containing materials trapped in the quasi filtration opening to be pulled back into the container, the quasi filtration opening is slightly taped with the lower end slightly larger than the upper end. To enable the flow facilitator 27 to function properly when the container 12 is tilted toward different directions, a plurality of the quasi filtration openings are formed around the periphery of the body 18. To reduce the cost, the body 18, porous filter 20, flow facilitator 27 and the blending/mixing mechanism 78 can be made as one part by injection molding or other suitable method.

[0050] In the exemplar embodiment described FIGS. 3-3 b, another alternative flow facilitator 27 is provided. Unlike the alternative flow facilitator of FIG. 2, here the quasi filtration openings 29 are formed directly around and near the outer periphery of the porous filter. The quasi filtration openings may be formed at the same time the porous filter is made or may be formed afterwards by manufacturing means such punching, melting, mechanically or laser drilling, or etching. Since here the length of liquid flow path through the quasi filtration openings 29 is about the same as that through the filtration openings in the porous filter 20, the quasi filtration openings may be smaller in size than those in FIG. 2 to reduce the amount of the flavor-containing materials may pass through the quasi filtration openings, thus preventing any measurable deterioration in beverage quality or taste. It was found that by having the quasi filtration openings sufficiently hydrophobic, the quasi filtration openings stay sufficient dry when they are contacted by the liquid or dispersion in the container. Such hydrophobic quasi filtration openings repels the liquid but let air pass through relatively freely, therefore may have smaller size than the liquid-wettable quasi filtration openings and even than the filtration openings of the porous filter 20. It is appreciated that the quasi filtration openings 29, either hydrophobic or liquid wettable, can be formed in a separate entity and later attached to porous filter 20, making it possible for the quasi filtration openings to have longer flow path than the filtration openings of the porous filter 20.

[0051] To prevent the body 18 from being pushed out by the dispersion 11 when the container is tilted to generate the liquid head (FIG. 3b), a cling-on chamber 79 is formed around the periphery of the body 18 to secure the body to the interior surface of the container 12. The cling-on chamber comprises an upper chamber wall 77, a lower chamber wall 74 and a chamber opening 75 between the upper and lower walls. The upper and lower walls 74 and 77 are made of resilient materials and conform to the interior surface of the container to form an air-tight seal to close the opening 75, thus closing the chamber 79. To generate a vacuum in the cling-on chamber when mounting the body 18 to the container, the upper and lower chamber walls are adapted, such as being sufficiently tall and resilient, to allow the cling-on chamber 79 to decrease in volume, thus expelling the air therein, when a user holds the handle 24 to push the body 18 downwards into the container and then to increase in volume, thus causing a vacuum in the cling-on chamber, after the user releases the handle. The container can be slightly taped to facilitate the insertion of the body 18 and the creation of the vacuum in the cling-on chamber. The vacuum generated in the cling-on chamber 79 causes the chamber to suck to the interior surface of the container.

[0052] In the exemplar embodiment described FIGS. 4 and 4a, the body 18 is irremovably attached to the container 12 to allow the cover 25 of the body 18 to seal the container and prevent the freshness loss of the flavor-containing materials in the container. A breakable or removable section 49 of the cover 25 is located near the left side of the container and a lever means 48, which is similar to that in the aluminum cans for soft drinks, is located above the breakable section to allow a user to pull the lever to break or remove the breakable section 49 and to form the beverage outlet 22. FIG. 4 shows the beverage device 10 after the breakable section 49 is broken by the lever means 48 and after hot water is added into the container through the beverage inlet 22 and through the porous filter 20 to extract the flavor-containing materials 37 in the container.

[0053] The flow facilitator 29 is formed on the porous filter by punching, melting or drilling a plurality of quasi filtration openings similar to those described in FIG. 3. It is preferably that the flow facilitator 29 is located at a location farther away from the breakable section 49 to better facilitate the filtration flow through the filtration openings of the porous filter when the container is tilted to generate a liquid head.

[0054] In addition to those functions described earlier, the flow facilitator 29 here allows air to get out of the container through the quasi filtration openings 27 when hot water is poured onto the porous filter to facilitate the filtration flow of the hot water into the container 12. It is also found that the flow rate through the filtration openings of the porous filter 20 can be further increased by shaking the container or repetitively tilting the container backward and forward. The flow facilitator prevents the flavor-containing materials in the dispersion 11 from passing through, thus from contaminating the beverage 44 from the filtration openings of the porous filter during the shaking or repetitive backward/forward tilting. It is believed that the shaking or repetitive backward/forward tilting causes the floated flavor-containing materials to precipitate to the bottom of the container and causes the dispersion 11 to reach and wash away the flavor-containing materials accumulated on the lower surface of the porous filter 20 during the filtration.

[0055] The porous filter 20 is attached to the lower surface of the cover 25 of the body 18. A dip-in chamber 63 is formed on the porous filter 20 to cause the filtration of the dispersion 11 through the porous filter before the container 12 is tilted, therefore making an amount of beverage 44 available in the dip-in chamber. A heat insulation member such as a sleeve 45 made from paper, foam or other insulation materials is attached, either removably or permanently, to the outside of the container 12 to prevent the hot liquid in the container from hurt the user when holding the container. It is appreciated that the porous filter can be attached to the top opening 14 of the container 12.

[0056] In the exemplar embodiment described FIG. 5, the body 18 and container 12 are formed together as one part with the bottom end of the body 18 connected to the top end of the opening 17 of the container. The porous filter 20 is attached to the bottom end of the body 18 to seal a supply of flavor-containing materials in the container. The flow facilitator 29 in this exemplar embodiment is the same and performs similar functions as the flow facilitator of FIG. 4. The cover 25 is removably attached to body 18 to prevent the freshness loss of the flavor-containing materials in the container.

[0057] To use the device 10, the cover 25 is partially removed to create a large enough opening as the beverage outlet and to allow hot water to be poured onto the porous filter as shown in FIG. 5. The cover can also be completely removed if desired. The hot water is poured onto the porous filter 20 and subsequently flows through the porous filter into the container to extract the flavor-containing materials 37 therein as the air leaves the container through the quasi filtration openings 29 of the flow facilitator 27. With the assistance of the facilitator 27, a user may further increase the flow rate of the beverage through porous filter 20 by shaking or repetitively tilting the container in the same as described in FIG. 4.

[0058] As described earlier in the method of using the device of FIG. 1, to make latte or mocha or other milk-based coffee drinks, water/milk or milk alone is added to the container instead of water. Regular hot milk is added to make latte and chocolate-flavored hot milk is added to make mocha. To make the taste of the new latte and mocha close to the conventional latte or mocha made from commercial or home espresso machines, a third cup of hot water may be first added into the container 12 first to extract the flavor-containing materials which is roasted coffee grounds here and later two thirds cup of hot or frothed milk is added into the container to mix with the dispersion 11. Latte or mocha can be made and dispensed by simply tilting the container as described above. The flavor-containing materials 37 may include a certain amount of powdered milk, cocoa and/or chocolate besides the roasted coffee grounds, therefore allowing one to brew mocha or latte by simply adding hot water into the container.

[0059] It is appreciated that when the hot liquid is poured onto the porous filter 20, the hot liquid overflow at the beverage outlet presents a safety issue. We found that by using a woven wire or plastic mesh filter which has less than 350 holes per inch, preferably less than 200 holes per inch, such issue may be resolved and the hot liquid can be poured onto the filter fairly fast without causing overflow. It is also noticed that by pouring the hot liquid onto a fixed spot or small area on the porous filter, the liquid flow through the porous filter into the container actually increases, thus helping preventing the hot liquid overflow issue.

[0060] As described above, the filtration flow through the porous filter 20 increases substantially if one shakes, swirls or repetitively back and forth tilts the container 12 before tilting to generate the liquid head and pour the drink. It was discovered that the filtration flow through the porous filter can be increased even further if the container is allowed to rest still after the container 20 has been shaken, swirled or repetitively tilted back and forth. It was also discovered, with a pleasant surprise, that by resting the container for about one minute or more, the amount coffee fines in the beverage from the beverage outlet 22 is significantly reduced. It is theorized that such movement of the container breaks a layer of floated coffee grounds in the container 20, thereby improving the filtration flow.

[0061] In FIGS. 6a-c, three alternative brew head assemblies 21 are described for the container 12 of FIGS. 1-3. In the brew head assembly of FIG. 6a, a transient storage chamber 54 is connected to the lower surface of the cover 25 for storing a supply of flavor-containing materials. The porous filter 20 adopts a taped cylindrical shape with its larger low peripheral edge attached to the lower end of the body 18 and its smaller top peripheral edge attached to the lower surface of the cover 25. The storage chamber comprises a cylindrical wall 53, a feed opening 56, a lid 55 for closing the feed opening, and a bottom plate 59 connected to the cylindrical wall 53 by hinge means 57. The bottom plate has a tab 61 at the opposite side of the hinge means for engaging with an outward protrusion 60 formed at the lower end of the cylindrical wall 53 to enable the bottom plate to close the storage chamber. A spring 58 with one end connected to bottom plate 59 and the other end to cylindrical wall 53 is loaded to facilitate the opening of the bottom plate after tab 61 is disengaged from protrusion 60.

[0062] The flow facilitator 27 in this alternative brew head assembly is the same as that of FIGS. 4 and 5. The blending/mixing mechanism 78 is similar to that of FIG. 1, but is slidingly engaged to an opening 81 at the center of the lid 55. In one design, the bottom plate 59 is opened manually by pushing the handle 24 downwards, which in turn pushes the rod 32, plate member 14 and the ground coffee 37 in the storage chamber 54 downwards, to disengage the tab 61 from the outward protrusion 60. In another design, the bottom plate 59 is opened automatically when the temperature around it or in the container 12 becomes sufficiently high to cause the bottom plate to expand thermally to disengage the tab 61 from the protrusion 60.

[0063] In the brew head assembly of FIG. 6b, the body 18 is formed from one sheet of formable materials such as polyester, polyolefin, polystyrene or polyacrylics by thermal or mechanical means to achieve very low cost. A thin chamber 50 is formed around body 18 to seal to the rim or top wall of container 12. The filter 20 can be a low cost cloth, paper, woven or non-woven polymer filter attachable to body 18. The flow facilitator is a check valve with the selective opening 29 formed on the porous filter, a seal member 51 for closing the selective opening when the dispersion reaches the facilitator and a keeper 52 for keeping the seal member below the selective opening. To achieve lower cost, this facilitator may be replaced by the facilitator of FIG. 5. With such low cost brew head assembly and a disposable cup as the container, the device 10, such as a coffeemaker or espresso machine, for making 1-8 cups of coffee or espresso can be manufactured at a cost of $0.1 to $0.2.

[0064] In the alternative brew head assembly of FIG. 6c, the blending/mixing mechanism 78 comprises a blade 69, an electric motor 46 mounted to the cover 25 of body 18, and rod 32 for connecting the motor to the blade through an opening 64 on the cover 25 and for transmitting the force or torque from the motor to the blade. The blade 69 may function to generate the top crema layer 15 on the dispersion 11, to mix the liquid with the flavor-containing materials, to grind the flavor-containing materials such as roasted coffee beans in the container, to break ice and flavor-containing materials, to blend flavor-containing materials and/or liquid to make various beverages, etc. The flow facilitator 27 and porous filter 20 are similar to their counterparts in FIG. 6a.

[0065] In FIG. 7, another exemplar embodiment of the invention is shown. The brew head assembly of FIG. 7 is similar to that of FIG. 6c except that the electric motor 46 of the blending/mixing mechanism 78 is mounted to a motor base 82 below container 12 and the blade 69 and rod 62 are rotationally connected to a container base 36 sealed to the bottom of the container. The rod 32 has a cavity 71 for engaging with shaft 72 of the motor when the container is removably received in cylindrical chamber 37 on motor base 82. A heater may be located in the base 36 or 82 to heat the container and the contents therein. Like the blending/mixing mechanism 78 of FIG. 6c, the blending/mixing mechanism here enables the device 10 to make all the drinks that can be made by coffee makers, espresso machines, blenders and mixers.

[0066] FIGS. 8-8 a show an improved version of the device of FIG. 5 and a method to brew various beverages with the improved device. In FIGS. 8 and 8a, the brew head assembly 21 is positioned substantially below the rim 107 of the cup 12 to form a sufficiently deep exchange chamber 108 above the second surface 62 of the porous filter 20 and an extraction chamber 109 below the first surface 61 of the porous filter to enclose the flavor-containing materials 37 such as roasted grounds. The exchange chamber 108 should be sufficiently deep to contain a supply of liquid, which liquid initially contains little or no flavor components from the flavor-containing materials 37 after the introduction of liquid into the cup 12. The depth of the exchange chamber can be about a quarter inches to two inches or even deeper depending on the shape and size of the container 12. The extraction chamber 109 encloses the flavor-containing materials 37 between its first surface 61 and the bottom 41 of the container and allows a dispersion 11 of the flavor-containing materials and liquid to be formed therein after the introduction of liquid into the cup. The extraction chamber should have a volume significantly larger than the volume of the flavor-containing materials 37 to enable the dispersion 11 to move relatively freely in the extraction chamber when the container is swirled or shaken. It was found that the volume of the extraction chamber should be about two or more times of the volume of the flavor-containing materials 37 for the dispersion 11 to move sufficiently free in the extraction chamber for the device 10 of FIG. 3. It is, however, appreciated that numerous factors such as the properties, size an thickness and shape of the porous filter 20 and the shape and size of the container 12 may affect the volumes and depths of the extraction chamber 109 and the exchange chamber 108 required for the proper operation of these two chambers.

[0067] It is discovered that by swirling or shaking the cup 12, the liquid in the exchange chamber 108 gradually becomes saturated with the flavor components from the flavor-containing materials 37 in the extraction chamber 109. Therefore, a reservoir of beverage 44 free of coffee grounds is formed in the exchange chamber 108 above the second surface 62 of porous filter 20 and is ready for drinking or dispensing. It is theorized that the shaking or swirling motion of the container 12 causes the liquid in the exchange chamber 108 to interchange with the liquid extraction in the extraction chamber 109 through the filtration openings 148 of the porous filter 20. As a result, the concentration of the flavor components in the liquid in the exchange chamber 108 increases gradually as the container is being swirled or shaken. It was found that it took about 5 to 60 seconds to raise the concentration of the flavor components in the exchange chamber 108 as high as that in the extraction chamber 109. The amount of time needed to equalize the concentrations in the exchange chamber and extraction chamber was found to depend on the thickness, shape and location of the porous filter 20, the size of the filtration openings 148 and the type and amplitude of the motions exerted to the container 12, and the size and shape of the extraction chamber and exchange chamber. Besides swirling and shaking, other motions such as vibration, repetitive back & forth tilting, repetitive expansion/contraction of the exchange and extraction chambers can also cause effective interchange of the liquid between the exchange chamber 108 and the extraction chamber 109.

[0068] It was also discovered that a visually appealing layer of crema 15 (FIG. 3a) is formed on top of the reservoir of beverage 44 in the exchange chamber after the container was swirled or shaken. Such a crema is known to be a sign of good quality coffee made by traditional espresso or coffee machines. It is also discovered that to reduce the amount of time needed to swirl or shake the container, the porous filter 20 between the exchange chamber 8 and extraction chamber 109 is preferred to be sufficiently large and thin with straight-through filtration openings. For example, when a thin wire mesh or a woven cloth with 200 or fewer straight holes per inch is used as the porous filter 20, the amount of swirling time needed to make a reservoir of saturated beverage in the exchange chamber is significantly less than when dense paper filter is used as the porous filter.

[0069] The device 10 of FIG. 8 has a line mark 106 formed or printed on the interior surface of the cup to indicate the right liquid level when one pours liquid into the cup to brew beverage. Here, the brew head assembly 21 comprises a porous filter 20 with its tapered peripheral edge heat sealed or staked to a gas-impermeable barrier film 105 laminated or coated on the side paper wall 111 of the cup 12. In this case, the upper part of the side wall of the cup 12 becomes the body 18 for the porous filter. A flow facilitator 27 having a plurality of selective openings 29 is located on the porous filter 20 to allow air to pass through from atmosphere into the extraction chamber but to restrict the flavor-containing materials from passing through when the container 20 is tilted to generate a liquid head to act on said first surface 61 of the porous filter to drive the liquid extraction out of the extraction chamber 109 through the filtration openings 148. The selective openings 29 can be equally spaced around the edge of the porous filter so that at least one selective opening is exposed to air on both the first and second surfaces 61 and 62 when the cup 12 is tilted.

[0070] To brew beverage, one pours liquid into the container until the liquid level reaches about the line mark 106. The user then swirls or shakes the container 12 and in 5 to 30 seconds a reservoir of beverage 44 with a visually appealing crema layer 15 will be produced in the exchange chamber 108 above the porous filter (FIG. 8a). The beverage 44 in the exchange chamber 108 may be drunk or poured out by slightly tilting the container 12. When the container is tilted more, a sufficient liquid head will be generated to act on the first surface 61 of the porous filter 20 to drive the liquid extraction in the extraction chamber 109 to the second surface 62 and subsequently to the exchange chamber and the beverage outlet 22.

[0071]FIG. 9 shows an alternative to the brewing device of FIG. 8. In this alternative, the porous filter 20 is attached to the bottom 41 of the cup to form the extraction chamber 109 between the first surface 61 of the porous filter and the bottom 41 to enclose a supply of flavor-containing materials 37. The exchange chamber 108 is formed between the second surface 62 of the porous filter and the side wall of the container and comprises a dip-in filtration chamber 63. The dip-in filtration chamber 63 is below the top end of the extraction chamber 109 and as a result the liquid extraction in the extraction chamber will flow from the extraction chamber into the dip-in filtration chamber when hot water is added into the extraction chamber.

[0072] A gas-impermeable film cover 25 having a strip tab or string connected to it for facilitating its removal may be attached to the bottom 41 outside the porous filter 20 to form a barrier enclosure for the supply of flavor-containing materials. The film cover 25 has been removed prior to introducing water into the cup and is thus not shown in FIG. 4. As in FIG. 8, the bottom 41 comprises a gas-impermeable barrier film 105 laminated or extrusion-coated on the paper cardboard 111. The side wall of the cup 12 may not need to have any gas-impermeable barrier film 105, therefore lowering the cost for the cup. It is appreciated that the porous filter 20 may be attached to a gas-impermeable plastic sheet or film disc (not shown) to form the extraction chamber 109 to enclose the supply of flavor-containing materials 37. The disc, together with the porous filter and the supply of flavor-containing materials on it, is then attached to the bottom of a low-cost conventional disposable paper cup. It is also appreciated that the porous filter can be made elastic and flexible enough to allow it to be pushed down or compressed towards the bottom 41 of the container by the gas-impermeable cover film 25, thereby allowing several such devices 10 to be stacked into each other for storage. It is also appreciated that the gas-impermeable cover film 25 may be sealed to the impermeable plastic sheet or film disc prior to attaching the assembly to the bottom 41 of the cup. It is also appreciated that the extraction chamber can be made tall to allow a top part of the porous filter to stick out of the liquid surface during brewing.

[0073] To make an iced latte with this brewing device, about ⅓ cup hot or boiling water is poured onto and through the porous filter 20 into the extraction chamber 109 to form a dispersion with the roasted coffee grounds in the extraction chamber. Part of the coffee extraction will flow out of the extraction chamber into the dip-in filtration chamber 63 of the exchange chamber 108. After about 1 minute, ice cube or crushed ice 178 and cold milk are introduced, either simultaneously or separately, into the exchange chamber 108. The container is then swirled or shaken for 5 to 20 seconds to produce a reservoir of iced latte 44 in the exchange chamber 108. To reducing spluttering, a lid may be placed on the cup 12 prior to swirling or shaking the cup 12. Chocolate milk may be used to replace the milk to make iced mocha.

[0074] The heat exchange from the ice 178 and/or cold milk in the exchange chamber 108 to the dispersion 11 in the extraction chamber 109 quickly quenches or stops further extraction of the flavor-containing materials 37 by water, therefore preventing certain bitter flavors or “bad” chemicals from being extracted out of the flavor-containing materials and improving the taste of the resulting latte.

[0075]FIG. 10 shows an improved version for the brewing device of FIG. 6b and a method for making iced coffee, latte and other beverages with the device. The improved device 10 comprises a disposable brew head assembly 21, a disposable cup 12 for containing a supply of flavor-containing materials 37. The disposable brew head assembly 21 comprises a thin formed plastic sheet 182 made from a thin plastic sheet such as polyester, polyolefin or polystyrene sheet by thermal or mechanical means to achieve very low cost. The thin formed plastic sheet 182 have a cover 25, a beverage outlet 22 and vent opening 28 formed on the cover, a cylindrical side wall 18 and a thin or narrow chamber 50 formed around the cylindrical body 18 to seal to the outer rim 107 of cup12. The disposable brew head assembly 21 further comprises a porous filter 20, which may be a low cost disposable paper filter, cloth filter or woven or non-woven plastic filter, attached to the cylindrical body 18 to form a substantially closed transient beverage chamber 23.

[0076] A neck 177 is formed below the narrow chamber 50 to form a lock with the outer rim 107 of cup 12 to prevent the brew head assembly from being dislodged by the liquid head that is to be generated to act on the first surface 61 of the porous filter 20 to drive the filtration flow through the filtration openings. An outwardly tapered flange 179 is formed below the neck 177 to facilitate the mounting of the brew head assembly 21 to the cup 12. A flow facilitator 27 comprises a second porous filter 183 having a plurality of selective openings 29 attached to the porous filter 20. The selective openings 29 are adapted to be either hydrophobic enough to prevent the liquid from entering selective openings 29 or smooth and large enough to cause the liquid in the selective openings 29 to be readily pulled out by a slight vacuum, pressure or vibration.

[0077]FIG. 10 is also used to illustrate a method to make iced beverage such as iced coffee or latte with this and other devices 10. To make an iced coffee, one pours hot or boiling water into the cup 12 to form a dispersion 11 with the roasted coffee grounds. After about 1 minute, ice cube or crushed ice 178 are added into the dispersion 11. The ice 178 quickly quenches or stops further extraction of the flavor-containing materials 37 by water, therefore preventing certain bitter flavors or “bad” chemicals from being extracted out of the flavor-containing materials and improving the coffee taste. The brew head assembly 21 is then mounted to the cup so that the rim 107 is received by the narrow chamber 50 and locked together by the neck 177.

[0078] To make an iced latte, about ⅓ cup hot or boiling water is poured into the cup to form a dispersion with the roasted coffee grounds. After about 1 minute, ice cube or crushed ice 178 and cold milk are introduced, either simultaneously or separately, into dispersion 11 to fill the cup. The ice 178 quickly quenches or stops further extraction of the flavor-containing materials 37. The brew head assembly 21 is then mounted to the cup so that the rim 107 is received by the narrow chamber 50 and locked together by the neck 177. To drink or dispense the iced latte, one simply tilts the cup 12 towards the beverage outlet 22 to generate a liquid head to act on the first surface 61 to drive the iced coffee through the porous filter and out of the beverage outlet 22.

[0079] Chocolate milk is used to replace the milk to brew iced mocha. To avoid dilution of the milk by water, one may heat ¾ to ¾ cup of milk and pour the hot milk into the cup 12 to form a dispersion 11 with the roasted coffee grounds. After about 1 minute of extraction by the hot milk, ice cube or crushed ice 178 are added into the dispersion 11 to quench the extraction process.

[0080] The scope of the invention is obviously not restricted or limited to the embodiments described by way of examples and depicted in the drawings, there being numerous changes, modifications, additions, and applications thereof imaginable within the purview of the claims. 

What is claimed is:
 1. A method for brewing a coffee beverage such as coffee, latte or mocha in a container from a supply of flavor-containing materials comprising roasted coffee grounds comprising: providing a brewing device comprising a porous filter having a first surface for contacting the flavor-containing materials and liquid in a container, a plurality of filtration openings for allowing liquid extraction to pass through as a beverage while blocking all or substantially all coffee grounds and a second surface for receiving the beverage from the plurality of filtration openings; a step of introducing liquid into the container to allow the formation of a dispersion containing the liquid and flavor-containing materials and the formation of a layer of floated flavor-containing materials on top of the dispersion; a step of tilting the container to generate a liquid head to act on the first surface of the porous filter to drive the liquid extraction through the plurality of filtration openings to the second surface of porous filter as a coffee beverage; and a step of breaking the layer of floated flavor-containing materials on top of the dispersion in the container, thereby preventing the clogging of the porous filter by the layer of floated flavor-containing materials and increasing the beverage flow through the filtration openings during said step of tilting.
 2. A method as defined in claim 1 wherein said step of breaking comprises one of a step of swirling the container, a step of shaking the container and a step of repetitively tilting the container back and forth.
 3. A method as defined in claim 1 wherein said device further comprises a flow facilitator comprising at least one selective opening, said selective opening being adapted to be sufficiently small to restrict the flavor-containing materials from passing through during said steps of breaking and tilting and adapted to be or become sufficiently permeable to air to allow air to enter the container during said step of tilting.
 4. A method as defined in claim 1 further comprising a step of regenerating the porous filter by moving the container in such a way to cause the liquid therein to wash the flavor-containing materials accumulated on the first or lower surface of the porous filter off into the container.
 5. A method as defined in claim 1 further comprising a step of regenerating the porous filter by causing the flavor-containing materials accumulated on the first surface of the porous filter to fall off or be washed off into the container, said step of regenerating comprising at least one of a step of swirling the container, a step of shaking or vibrating the container and a step of tilting the container back and forth.
 6. A method as defined in claim 1 further comprising a step of resting the container in a substantially still position for a period of time after said step of breaking, said step of resting causing further increase of the filtration flow through the filtration openings.
 7. A method as defined in claim 1 further comprising a step of adding flavor-containing materials into a transient storage chamber and a step of delivering the flavor-containing materials therein into the container after the transient storage chamber or container has been heated to a certain temperature.
 8. A method as defined in claim 1 wherein said step of breaking comprises a step of moving one of a plate, a rod and spoon in a repetitive, substantially circular or linear motion within the container.
 9. A method as defined in claim 1 wherein said porous filter is irremovably or permanently connected to the container to form a closed chamber for enclosing a supply of roasted coffee grounds in the closed chamber, wherein said step of introducing liquid comprises a step of pouring liquid onto the second surface of the porous filter, and a step of filtering the liquid into the closed chamber and to the supply of roasted coffee grounds therein.
 10. A method as defined in claim 1 further comprising providing a supply of roasted coffee grounds to be extracted by the liquid and a supply of milk or the like solids to be dissolved by the liquid introduced into the container during the step of introducing, thereby producing a freshly brewed latte or the like milk-based coffee drink during said step of tilting.
 11. A method for making beverage from flavor-containing materials with a device having a container, a porous filter and a blade comprising a step of introducing flavor-containing materials comprising roasted coffee beans into the container; a step of grinding the flavor-containing materials in the container to produce ground flavor-containing materials therein by the blade; a step of introducing liquid into the container; a step of extracting the aroma and/or flavor compounds out of the ground flavor-containing materials with the liquid in the container to produce a beverage; and a step of tilting the container to generate a liquid head to drive the beverage out of the container through the porous filter.
 12. Method for making beverage as defined in claim 1 I further comprising a step of turning the blade to stir the flavor-containing materials and liquid to form a dispersion in the container or to produce a visually appealing crema layer on the beverage.
 13. Method for making beverage as defined in claim 11 further comprising a step of heating the liquid in the container.
 14. A method for brewing milk-based coffee drinks such latte, cappuccino and mocha in a container from a supply of roasted coffee grounds comprising: providing a device comprising a porous filter having a first surface adapted to contact roasted coffee grounds, a plurality of filtration openings adapted to allow liquid extraction to pass through while block substantially all roasted coffee grounds and a second surface for receiving the liquid extraction from the filtration openings; a step of introducing a first amount of hot water into a container to produce a dispersion comprising the hot water and roasted coffee grounds; a step of allowing the hot water to extract the roasted coffee grounds for a certain amount of time in the dispersion to produce a strong dose of coffee extraction; a step of introducing a second amount of hot or frothed milk into the container to produce a dispersion of the roasted coffee grounds and the milk-containing coffee drink; and a step of tilting the container to generate a liquid head to act on the first surface of the porous filter to drive the milk-containing coffee drink through the filtration openings to the second surface of the porous filter and out of the container as a freshly brewed milk-based coffee drink.
 15. A method for brewing milk-based coffee drinks such latte, cappuccino and mocha as defined in claim 14 wherein the first amount of hot water in said step of introducing a first amount is about ⅓ cup of hot water and the second amount of hot or frothed milk in said step of introducing a second amount is about ⅔ cup of hot or frothed milk.
 16. A method for brewing a beverage such as coffee, latte or mocha from a supply of flavor-containing materials comprising: providing a disposable brewing device comprising a disposable container including one of a disposable cup, can and bottle, a disposable porous filter permanently or irremovably connected to the disposable container by one of a direct connection in which the porous filter is directly attached to the disposable container and an indirect connection in which the porous filter is attached to a body and the body is attached to the disposable container, a supply of flavor-containing materials in the disposable container and a cover for sealing the device to maintain the freshness of the flavor-containing materials therein, the porous filter having a first surface adapted to contact the flavor-containing materials, a plurality of filtration openings for allowing liquid extraction to pass through as a beverage while blocking all or substantially all solids and a second surface for receiving the beverage from the plurality of filtration openings; a step of removing at least part of the cover to make at least part of the second surface of the porous filter accessible; a step of pouring hot liquid including at least one of hot water and hot milk onto the second surface of the porous filter to cause the liquid to filter through the filtration openings to the flavor-containing materials in the disposable container, wherein the hot liquid forms a dispersion with the flavor-containing materials and extracts the flavor-containing materials to form a liquid extraction; and a step of tilting the device to generate a liquid head to act on the first surface of the porous filter to drive the liquid extraction in the disposable container through the plurality of filtration openings as to the second surface of porous filter as a freshly brewed beverage.
 17. A method for brewing a beverage such as coffee, latte or mocha as defined in claim 16 further comprising a step of disposing the brewing device after the beverage flow to the second surface of porous filter and out of the disposable container becomes a thin stream or drip-wise, thereby saving consumers from the traditional time-consuming cleaning job after brewing a coffee beverage.
 18. A method for brewing a beverage such as coffee, latte or mocha as defined in claim 16 wherein the disposable brewing device further comprises a chamber above the second surface of the porous filter and the method further comprising a step of introducing an amount of additive or additives into the chamber, wherein said step of pouring hot liquid comprises a step pouring hot liquid onto the additive in the chamber to dissolve and carry the additive through the filtration openings into the disposable container.
 19. A method for brewing an iced or cold coffee beverage such as iced coffee, iced latte and iced mocha in a container from flavor-containing materials comprising roasted coffee grounds comprising: providing a device comprising a porous filter having a first surface adapted to contact roasted coffee grounds, a plurality of filtration openings adapted to allow liquid extraction to pass through while block substantially all roasted coffee grounds and a second surface for receiving the liquid extraction from the filtration openings; a step of introducing liquid into a container to produce a dispersion comprising the liquid and roasted coffee grounds; a step of allowing hot liquid to extract the roasted coffee grounds for a certain amount of time in the dispersion to produce a liquid extraction; a step of adding an amount of ice into the container to substantially quench or stop the extraction of the roasted coffee grounds, thereby preventing over-extraction of the roasted coffee grounds by the liquid and improving the taste of the resulting coffee beverage; and a step of tilting the container to generate a liquid head to act on the first surface of the porous filter to drive the liquid extraction through the filtration openings to the second surface of the porous filter and subsequently out of the container as the iced coffee beverage.
 20. A method for brewing an iced or cold beverage as defined in claim 19 wherein said step of introducing liquid comprises a step of introducing a first amount of hot liquid including one of hot water and hot milk into the container before said step of allowing hot liquid to extract and a step of introducing a second amount of cold liquid including one of cold milk and cold water after said step of allowing hot liquid to extract.
 21. A method for brewing an iced or cold beverage as defined in claim 19 further comprising a step of moving the container according to at least one of a swirling, shaking, repetitive tilting and vibrating motions to cause the liquid extraction in an extraction chamber to interchange with the liquid in an exchange chamber through the filtration openings of the porous filter, wherein during said step of adding ice the ice is added into the exchange chamber of the container.
 22. A method for brewing an iced or cold beverage as defined in claim 19 further comprising a step of connecting the device to the container prior to said step of tilting, wherein during said step of adding ice the ice is added directly into the dispersion, thereby allowing intimate contact between the ice and the roasted coffee grounds in the dispersion to achieve a fast quenching of the extraction.
 23. A method for brewing an iced or cold beverage as defined in claim 19 further comprising providing a disposable cup as the container, wherein the device is a disposable device connected or adapted to connect to the disposable cup, thereby allowing a user to simply discard the disposable cup and device when iced coffee beverage stops or substantially stops flowing out of the disposable cup during a step of tilting.
 24. A method for brewing a beverage such as coffee, espresso, cappuccino, latte or mocha from flavor-containing materials comprising: providing a device comprising a porous filter having a first surface adapted to contact flavor-containing materials and liquid, a filtration opening adapted to allow liquid extraction to pass through and a second surface for receiving the liquid extraction from the filtration opening; a step of introducing liquid into an extraction chamber containing a supply of flavor-containing materials and into an exchange chamber, the liquid in said extraction chamber forming a dispersion with and interacting with the flavor-containing materials therein to produce a liquid extraction; and a step of causing the liquid in the exchange chamber to interchange with the liquid extraction in the extraction chamber through the filtration opening of the porous filter to cause the concentration of the flavor components in the liquid in the exchange chamber to increase, thereby producing in the exchange chamber a reservoir of liquid extraction or beverage.
 25. A method as defined in claim 24 wherein said step of causing comprises at least one of a step of swirling the container, a step of shaking the container, a step of vibrating the container, and a step of repetitively tilting the container back and forth.
 26. A method as defined in claim 24 further comprising a step of tilting the container to pour the beverage out of the exchange chamber and to generate a liquid head to act on the first surface to drive the liquid extraction in the extraction chamber through the filtration openings to the second surface of the porous filter.
 27. A method as defined in claim 24 further comprising a step of heating the liquid in the extraction chamber.
 28. A method as defined in claim 24 further comprising a step of adding an amount of soluble additive into the exchange chamber, wherein the additive is dissolved by the liquid and distributed into the extraction chamber substantially uniformly during said step of moving.
 29. A method for brewing a coffee beverage such as coffee, espresso, latte or mocha from a supply of flavor-containing materials comprising roasted coffee grounds comprising: providing a brewing device comprising a porous filter and a flow facilitator having at least one selective opening for increasing the beverage flow through the porous filter, the porous filter having a first surface adapted to contact roasted coffee grounds, a plurality of filtration openings to filter a liquid extraction to produce a coffee beverage and a second surface for receiving the beverage from the filtration openings; a step of introducing liquid to a supply of flavor-containing materials comprising roasted coffee grounds in a container, which container is adapted to be sufficiently large to allow a dispersion of the liquid and the flavor-containing materials therein; a step of tilting the container to generate a liquid head to act on the first surface of the porous filter, the liquid head causing the dispersion to be filtered through the filtration openings to the second surface of the porous filter as a beverage; and wherein the at least one selective opening is sufficiently small to restrict the roasted coffee grounds from passing through during said step of tilting, thereby ensuring that the coffee beverage on the second surface of the porous filter is substantially free of the roasted coffee grounds, and is or becomes sufficiently permeable to air to allow air to enter the container during said step of tilting, thereby preventing vacuum formation in the container and increasing the beverage flow from the first surface to the second surface of the porous filter. 